RU2163739C1 - Antenna - Google Patents

Abstract

FIELD: radio engineering; antenna-feeder assemblies, primarily small-size broad-band antennas. SUBSTANCE: device has helix antenna assembled of conductors which are arranged in one plane to form bifilar helix. Two antenna members are arranged in mentioned plane and differentially connected to conductors of extreme turns of bifilar helix. Bifilar helix is rectangular in shape made in the form of line sections with straight corners of turns. Each antenna member is made in the form of equilateral trapezium and connected to conductor lead at apex of smaller base of equilateral trapezium. Bases of equilateral trapeziums are parallel to line sections of bifilar helix. EFFECT: improved performance characteristics. 14 cl, 5 dwg

Description

 The invention relates to radio engineering and can be used in antenna-feeder devices, mainly in small ultrawideband antennas.

 A known spiral antenna formed of conductors located in the same plane and made in the form of a two-way rectangular spiral, the turns of which are directed opposite each other (1).

 A spiral antenna is relatively wider than other types of antennas: vibrating, loop, V-shaped, rhombic, etc.

 A limitation of this antenna is the significant dimensions of the two-way helix with the need to increase broadband, especially increasing to ensure operation at low frequencies.

 An antenna is also known, containing antenna elements located in the same plane and connected opposite to each other (2).

 In this technical solution, the antenna elements are made of plates in the form of isosceles triangles facing their vertices and their opposite sides are parallel to each other. The advantage of the antenna is its construction on the basis of the principle of self-complementarity, in which the metal part in shape and size corresponds to and is equal to the slotted part complementing it in the plane. Such an infinite structure has a purely active and frequency-independent input impedance, which improves its coordination in a wide frequency range.

 The limitation of the device is to reduce the broadband input impedance due to the finiteness of its geometric dimensions.

 The closest technical solution is an antenna containing a spiral antenna formed of conductors located in the same plane and made in the form of a two-way spiral, the turns of which are directed opposite each other, two antenna elements located in the specified plane and connected opposite to each other to the conductors of the extreme turns two-way spirals for each conductor of one and the other approach of the two-way spiral, respectively (3).

 The antenna elements in this device are a symmetric (or asymmetric) half-wave vibrator, and the vibrator shoulders are made of two pins. This technical solution manages to somewhat eliminate the disadvantages of the known devices. The spiral antenna operates in the high-frequency part of the range, while the boundary of the range, relative to the lower frequencies, is determined by the diameter of the antenna and is of the order of 0.5λ, where λ is the working wavelength. Starting from these frequencies, a half-wave vibrator is turned on. The half-wave vibrator can be connected to either the external or internal ends of the spiral antenna.

The limitations of the closest analogue are as follows:
- significant geometric dimensions, as the dimensions of the spiral should be at least 0.5λ, and the dimensions of the symmetrical vibrator 0.5λ _max ;
- insignificant broadband, since the half-wave vibrator is a narrow-band device, and at the points of connection of the shoulders of the vibrator, the input impedance changes in frequency, which has a significant effect on the broadband of the system;
- poor quality of coordination due to the galvanic connection of two antenna systems with different resistances.

 The problem solved by the invention is to increase technical and operational characteristics and expand the arsenal of used technical means.

 The technical result that can be obtained by performing the claimed antenna is an increase in broadband, an improvement in the standing wave coefficient SWR, a simplification of the design, and a reduction in size.

 To solve the problem with achieving a technical result in a known antenna containing a spiral antenna formed of conductors located in the same plane and made in the form of a two-way spiral, the turns of which are directed opposite each other, two antenna elements located in the specified plane and connected opposite to each other friend to the ends of the conductors of the extreme turns of the two-way spiral, respectively, according to the invention, the two-way spiral is made rectangular, in the form of line segments with At right angles of the turns, each of the antenna elements is made in the form of an isosceles trapezoid and is connected to the end of the conductor at the top of the smaller base of the isosceles trapezoid, and the bases of the isosceles trapezoid are parallel to the line segments of the two-way spiral.

There are additional options for the design of the antenna, in which it is advisable that:
- line segments of the double-helix were made rectilinear;
- the conductors were made in the form of a two-way square-shaped spiral;
- the distances between the opposite vertices of the large bases of the equal-sided trapezoid of the antenna elements were equal to each other, and the distances between all adjacent vertices of the large bases were equal;
- the gaps between the conductors of the double-helix and the thickness of the conductors were chosen equal to each other;
- the length L of the smaller base of the isosceles trapezoid was made equal to L = l + 2 δ, where
l is the length of a straight line segment of a turn of a two-way spiral facing the base of an equal-sided trapezoid,
δ is the gap between the turns of the double-helix;
- the antenna element was formed from a continuous plate;
- the antenna element was formed from a zigzag filament made of conductive, and the bending angles of the zigzag filament were selected corresponding to the shape of an equal-sided trapezoid, while the parts of the zigzag zigzag filament are made coincident with the sides of the equal-sided trapezoid, and the connecting parts of the zigzag zigzag filament are parallel to the zigzag trapezoid base;
- the gaps between the conductors of the double-helix were chosen equal to the gaps between the parts of the zigzag filament, parallel to the bases of the equal-sided trapezoid;
- the zigzag filament of the antenna elements along its longitudinal axis was meander-shaped;
- a zigzag thread of antenna elements along its longitudinal axis was made in the form of a structure with a constant step, which between constant steps is determined by a pseudorandom sequence of numbers 0 and 1 with an equal average frequency of occurrence of these numbers;
- each of the conductors along its longitudinal axis was made meander-like;
- each of the conductors of the double-helix was made along its longitudinal axis in the form of a structure with a constant step, which between constant steps is determined by a pseudo-random sequence of numbers 0 and 1 with an equal average frequency of occurrence of these numbers;
- conductors and antenna elements were made with high resistivity.

 Due to the implementation of the claimed antenna in the form of a two-way rectangular helix and the use of antenna elements made in the form of an equal-sided trapezoid, it was possible to solve the problem. This is achieved by the fact that a generalized antenna system (AS) is built on the basis of the principle of self-complementarity; its element is a double-entry rectangular spiral of Archimedes; the continuation of the two-way spiral is made in the form of plates with a width that increases linearly with distance from the center of the spiral, or in the form of a zigzag conductive thread filling the area of these plates. An additional gain in speaker broadband is achieved through the implementation of all meander-shaped conductors and from a material with high resistivity.

 FIG. 1 depicts the configuration of the claimed antenna - with antenna elements in the form of isosceles trapezoidal plates.

 FIG. 2 is the same as FIG. 1, is a two-way rectangular spiral of Archimedes, the continuation of which is a zigzag thread with a width that increases linearly with distance from the center of the spiral.

 FIG. 3 is the same as FIG. 1, in which all the conductors and zigzag threads of the antenna elements are made meander-like.

 FIG. 4 is the same as FIG. 1, in which all the conductors and zigzag threads of the antenna elements are made in the form of a meander-shaped non-periodic structure with a constant step, the periods in which are determined by a pseudorandom sequence of numbers 0 and 1 with an equal average frequency of occurrence of these numbers.

 FIG. 5 is a graph of a standing wave coefficient SWR reduced to a wave impedance of 75 ohms.

 Small-sized ultra-wideband antenna (Fig. 1) contains a spiral antenna 1 formed of conductors located in the same plane and made in the form of a two-way spiral. The turns of the two-way spiral are directed counter-to each other. The conductors of the spiral antenna 1 are made in the form of line segments with right angles of turns.

 Two antenna elements 2 are located in the plane of the double-helix. Antenna elements 2 are connected oppositely to each other to the conductors of the extreme turns of the two-way spiral for each conductor of one and the other approach of the two-way spiral, respectively. Each of the antenna elements 2 is made in the form of an isosceles trapezoid and is connected to the end of the conductor at the apex of the smaller base of the isosceles trapezoid. The bases of the equal-sided trapezoid are parallel to the line segments of the double-helix spiral antenna 1. Line segments of the double-helical spiral in a particular case can be made rectilinear. Simplification of the design and reduction of its dimensions is achieved by making the device planar, in which all its individual elements are located in the same plane. Such a device is easy to implement structurally and technologically in microstrip design. Broadband and improvement of the standing wave coefficient is achieved by performing a single speaker, in which all elements are located in the same plane and satisfy the principle of self-complementarity.

 To fully meet the criteria for conditions of self-complementarity, the conductors of the spiral antenna 1 (Fig. 1) can be made in the form of a two-way square spiral with vertices of the right angles of each coil located at the vertices of the square at equal distances along the diagonal and along the sides of the imaginary square, taking into account the difference arising from - for the gap between the conductors for their location in accordance with the shape of the spiral of Archimedes.

 The distances between the opposite vertices of the large bases of the equal-sided trapezoid of the antenna elements 2 can also be chosen equal in this design, as well as the distances between all adjacent vertices of the large bases are chosen equal. In this embodiment of the invention, the vertices of the large bases of the equal-sided trapezoid of the antenna elements 2 (Fig. 1) are placed in places corresponding to the vertices of an imaginary square to build the entire antenna system (AS) based on the principle of self-complementarity.

 The values of the gaps between the conductors and the thickness of the conductors of the two-way helix of the spiral antenna 1 in the embodiment are chosen equal to each other.

The length L of the smaller base of the equal-sided trapezoid of the antenna elements 2 is made equal to L = l + 2 δ, where
l is the length of a straight line segment of a turn of a two-way spiral facing the base of an equal-sided trapezoid,
δ is the size of the gap between the turns of the double-helix.

 In this embodiment, the vertices of the isosceles trapezoid are located exactly on the diagonal of the imaginary square.

 Antenna element 2 (Fig. 1) can be made directly from the conductive plate, which, in comparison with the closest analogue, allows to increase broadband, improve the standing wave coefficient SWR and reduce the dimensions of the device. The spiral antenna 1 is made of turns with right angles, and the antenna elements 2 are combined with it, they are not separate elements described, for example, in (2), but in combination with the spiral antenna 1 satisfy the principle of self-complementarity.

 However, the broadband can be further increased if the antenna element 2 (Fig. 2) is formed from a zigzag filament 3 made conductive. The bending angles of the zigzag thread 3 are selected corresponding to the shape of an isosceles trapezoid. The zigzag parts of the zigzag thread are made coincident with the lateral sides of the imaginary isosceles trapezoid, and the parts of the zigzag zigzag threads connecting them are parallel to the bases of the imaginary isosceles trapezoid. In this case, the zigzag thread 3 (Fig. 2) visually fills the entire area of these plates (Fig. 1).

 To satisfy the principle of self-complementarity, the gaps between the conductors of the double-helix spiral (Fig. 2) are chosen equal to the gaps between the parts of the zigzag filament located parallel to the bases of the equal-sided trapezoid.

 The broadband capability of the device as a whole can be further enhanced if the zigzag thread 3 of the antenna elements 2 is meander-shaped along its longitudinal axis (Fig. 3). For this, each of the conductors of the spiral antenna 1 along its longitudinal axis is made meander-like. The conductor shape of the helical antenna 1 is shown at 4 in FIG. 3 magnified.

 To suppress local resonances, which can lead to an increase in the KBW and to further increase the broadband of the device as a whole, it is advisable that the zigzag thread of 3 antenna elements 2 along its longitudinal axis be made in the form of a meander-like structure with a constant step, which between constant steps is determined by a pseudorandom sequence of numbers 0 and 1 with an equal average frequency of occurrence of these numbers (Fig. 4). Similarly, in the form of a meander-like structure with a constant step, which between constant steps is determined by a pseudorandom sequence of numbers 0 and 1 with an equal average frequency of occurrence of these numbers, each of the conductors of the spiral antenna 1 can be made. The shape of the conductor of the spiral antenna 1 is shown at 5 in FIG. 4 enlarged, and the corresponding part of the pseudorandom sequence is inscribed above a fragment of a non-periodic meander-like structure.

 The conductors of the spiral antenna 1 and antenna elements 2 both when they are made in the form of plates, and when they are made in the form of a zigzag filament (Fig. 1-4) can be made with high resistivity. For example, for antenna elements 2 of plates with a resistive layer deposited on them with a gradually increasing resistance value towards the base of an equal-sided trapezoid of a larger length. And for the conductors of the spiral antenna 1 and for the zigzag thread 3 of the resistive wire with a smoothly changing resistance from the center of the antenna system (AC) to its edges.

 A small ultra-wideband antenna works (Fig. 1-4) as follows.

 At low frequencies, the spiral antenna 1 (the square-shaped two-way spiral of Archimedes) functions as a two-wire transmission line, which gradually passes into the radiating structure - antenna elements 2 in the form of an isosceles trapezoid. Antenna elements 2 are either conductive plates (Fig. 1), with a width that increases linearly with distance from the center of the spiral, or a zigzag thread 3 (Fig. 2), filling the area of isosceles trapezoid.

The implementation (Fig. 3) of the conductors of the spiral antenna 1 and the zigzag filament 3 meander-shaped (in the form of position 4) allows you to create the speed of the traveling current wave, equal to approximately 0.4-0.5 of the speed of the current wave along a smooth structure. Therefore, despite the small geometric dimensions of the antenna system, λ _max / 10, where λ _max is the maximum wavelength, its relative electric length is large.

 At the lower and middle frequencies of the range, the radiation pattern is the same as that of a broadband symmetric vibrator with SWR <4 (Fig. 5). At higher frequencies, when the dimensions of the square-shaped spiral of Archimedes become equal to λ / 7, where λ is the working wavelength, the two-way spiral is the main radiating structure. At high frequencies, the range properties of the antenna system are limited by the accuracy of the fulfillment of the excitation conditions and by a change in the radiation pattern. The standing wave coefficient SWR varies in the frequency range from 1.5-3 (Fig. 6).

 The device is made using the principle of self-complementarity, i.e., the metal and slotted parts are absolutely identical in shape and size, which ensures a constant input resistance of R ≈ 100 Ohms in a wide finite frequency band. The use of the square-shaped spiral of Archimedes is due to the geometric dimensions 4 / π times smaller than the circular one. The use of inhibitory structures and the absence of galvanic connections between elements can improve the coordination of the device with the supply line with its small geometric dimensions. A conical balancing transformer, which is a smooth transition from a coaxial line to a two-wire line, can serve as an exciting device of the antenna.

 The most successfully declared antenna can be industrially applicable in the radio industry when creating antenna-feeder devices with improved technical and operational characteristics.

Sources of information
1. Ultra-wideband antennas, translation from English Popova and V.A. Zhuravlev, ed. L.S. Benenson. M.: Mir, 1964, p. 151 - 154.

 2. A.Z. Fradin. Antenna-feeder devices, M .: Communication, 1977

 3. US patent N 5257032, H 01 Q 1/36, publ. 10/26/93.

Claims (14)

 1. An antenna containing a spiral antenna formed of conductors located in the same plane and made in the form of a two-way spiral, the turns of which are directed opposite to each other, two antenna elements located in the specified plane and connected opposite each other to the ends of the conductors of the extreme turns of the two-way spiral accordingly, characterized in that the two-way spiral is made rectangular, in the form of line segments with right angles of turns, each of the antenna elements is made in the form of an isosceles tr trapezoid and is coupled to an end of the conductor at a vertex of the smaller base of an isosceles trapezoid, and the base of an isosceles trapezoid disposed in parallel lines segments double helix.  2. The antenna according to claim 1, characterized in that the line segments of the double-helix are made rectilinear.  3. The antenna according to claim 1, characterized in that the conductors are made in the form of a two-way square-shaped spiral.  4. The antenna according to claim 3, characterized in that the distances between the opposite vertices of the large bases of the isosceles trapezoid antenna elements are equal to each other, and equal to the distance between all adjacent vertices of the large bases.  5. The antenna according to claim 1, characterized in that the gaps between the conductors of the double helix and the thickness of the conductors are chosen equal to each other. 6. The antenna according to claim 5, characterized in that the length L of the smaller base of the equal-sided trapezoid is made equal
L = l + 2δ,
where l is the length of the straight line segment of the turn of the double-helix, facing the base of the isosceles trapezoid;
δ is the size of the gap between the turns of the double-helix.  7. The antenna according to claim 1, characterized in that the antenna element is formed of a continuous plate.  8. The antenna according to claim 1, characterized in that the antenna element is formed from a zigzag filament, the bending angles of the zigzag filament being selected corresponding to the shape of an equal-sided trapezoid, while the zigzag part of the zigzag filament is made coincident with the sides of the equal-sided trapezoid, and the connecting parts of the zigzag zigzag zigzag the threads are parallel to the bases of the isosceles trapezoid.  9. The antenna according to claim 8, characterized in that the gaps between the conductors of the double-helix are selected equal to the gaps between the parts of the zigzag filament parallel to the bases of the equal-sided trapezoid.  10. The antenna of claim 8, wherein the zigzag filament of the antenna elements along its longitudinal axis is made meander-like.  11. The antenna according to claim 9, characterized in that the zigzag filament of the antenna elements along its longitudinal axis is made in the form of a structure with a constant step, which between constant steps is determined by a pseudorandom sequence of numbers 0 and 1 with an equal average frequency of occurrence of these numbers.  12. The antenna according to claim 1, characterized in that each of the conductors along its longitudinal axis is meander-shaped.  13. The antenna according to claim 12, characterized in that each of the conductors of the two-way helix is made along its longitudinal axis in the form of a structure with a constant step, which between constant steps is determined by a pseudorandom sequence of numbers 0 and 1 with an equal average frequency of occurrence of these numbers.  14. The antenna according to claim 1, characterized in that the conductors and antenna elements are made with high resistivity.

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